Lipid peroxidation, a central event in atherogenesis and NASH, results in formation of oxidation-specific epitopes (OSE) such as oxidized phospholipids (OxPL), malondialdehyde (MDA) and complex MDA adducts termed MAA, which we termed ?oxidation-specific-epitopes? (OSE). They are proinflammatory and promote chronic inflammation. Because OSE are mostly products of non-enzymatic lipid peroxidation, mechanisms to specifically neutralize them were unavailable until now and their actual roles in vivo in disease states such as atherosclerosis and NASH are unknown. Project 3 is focused on understanding the role of OSE in both atherosclerosis and NASH and the common (or unique) mechanisms by which they contribute to these diseases. This is now feasible based on our recent development of transgenic mice that constitutively express single chain antibodies that target OxPL--the E06-scFv mice?or target MDA/MAA?the IK17-scFv mice. In recently published and new preliminary data we demonstrate that targeting OxPL in mice consuming NASH producing diets decreases both atherosclerosis and NASH. Preliminary studies demonstrate that targeting of MDA/MAA can also reduce the progression of atherosclerosis and hepatic inflammation in a NASH model. Patients with NASH are at increased risk for CVD, and share common risk factors. However, NASH confers additional risk for CVD above that due to known shared risk factors. This Application will test the hypothesis that OSE are a previously unrecognized common risk factor. Uniquely, this project will simultaneously focus on the role of OSE in the pathogenesis of atherosclerosis and NASH and define common (or distinct) mechanisms by which OSE promote these diseases.
Specific Aim 1 will use the E06-scFv transgenic mice to study the Role of OxPL in Atherosclerosis and Hepatic Steatosis/NASH/Fibrosis in mouse models and determine if targeting OxPL can simultaneously reduce disease burden in both the artery and liver. We will use the E06-scFv mice to investigate the specific mechanisms by which neutralization of OxPL impacts atherogenesis and liver disease.
Specific Aim 2 will study the Role of MDA/MAA in Atherosclerosis and Hepatic Steatosis/NASH/ Fibrosis in mouse models in parallel studies to Aim 1.
Specific Aim 3 are Translational Studies of the Role of OSE in CVD and NAFLD/NASH and will seek to determine if targeting OxPL and/or MDA/MAA can not only prevent progression of disease but cause regression of existing disease. This will be accomplished by generating transgenic mice that conditionally express the antibodies targeting OSE so that enhanced titers can be achieved after disease is established. This will allow studies to determine if targeting OSE can be therapeutic and reduce disease burden. These studies should provide an understanding of novel common risk factors connecting NASH and atherogenesis. Because an antibody-mediated approach to neutralize OSE could target both NASH and atherogenesis simultaneously, these studies may lead to innovative translational applications.
Patients with NASH are at increased risk for CVD, and share both identified and unknown common risk factors. This Project will test the hypothesis that oxidation-specific epitopes, which are common products of lipid peroxidation, are a common risk factor mediating both diseases. Using mice that express antibodies that target OSE, we will determine if neutralizing OSE simultaneously reduces both NASH and atherogenesis. These studies might then suggest novel translational approaches to reducing both NASH and CVD.
